Releasable metalized embossed transfer film

ABSTRACT

A releasable transfer film is suitable to provide a metalized embossed composite onto a paper substrate without a release layer between the composite and a polymeric carrier layer. The transfer film includes a polymeric base layer, an embossing material layer and a metal layer. The transfer film is bonded to the paper substrate with an adhesive layer allowing the polymeric barrier layer to peel away from and to expose the metal-backed, embossing material layer. The substrate covered with the metalized embossed composite can be used to impart holographic style images to packaging, printed media products such as magazines.

This application claims benefit of U.S. provisional application No.61/359,196 filed Jun. 28, 2010.

FIELD OF THE INVENTION

This invention relates to the fabrication of metalized diffractionpatterned coatings on substrates. More specifically it relates to areleasable film for transferring a metalized, embossable defractionpattern coating onto a paper-based substrate.

BACKGROUND OF THE INVENTION

Various commercial consumer goods are increasingly using glossyholographic style imaging. These image effects are appearing on productpackaging such as, for example, toothpaste and magazine covers.

The holographic style image is created by light reflecting from anobject, the outer layers of which include an outermost diffractionpattern-embossed coating, a metalization layer, an adhesive layer and asubstrate layer. The diffraction pattern coupled with the reflectiveproperty of the metal creates the holographic effect. The adhesive layerbonds the metalized surface of the embossed coating to the substrate.Typically the substrate is a paper or paper-like composition.

Generally, the multilayer composite is created in several stepsutilizing coating transfer. A conventional process involves applicationof a release layer onto a carrier film. Then an embossing material layeris placed on the release layer. The diffraction pattern is next createdby embossing the carrier/release/coating composite. Next, the exposedand embossed surface of the coating layer is metalized, i.e., a thinlayer of reflective metal is deposited thereon. The substrate isprepared by applying to its outer surface a layer of suitable adhesive.The metalized surface of the carrier film composite is joined to theadhesive-bearing substrate after which the adhesive is activated to forma permanent bond. Lastly, the carrier film is pulled away from thesubstrate. Separation of the release layer from the coating layertransfers the embossed metalized coating layers adhered to thesubstrate. The substrate is then incorporated into selected end useapplications.

Common traditional processes suffer from the need to employ a releaselayer between the carrier and the embossing material layer. The releaselayer composition provides compatibility between the carrier materialand the coating material such that they can be carried through theembossing and metalizing steps while remaining intact. The release layeralso must have a properly weak bond to the coating layer such that afteractivating the permanent adhesive layer, the carrier with release layercan cleanly strip away from the finished substrate. Use of release layeradds to the cost of the materials, cost of equipment to apply thematerials and complexity of the process for making the product. Inshort, use of a release layer is undesirable as it reduces productivityand increases cost to of the holographic style image-bearing substrateproduct.

Another conventional holographic image transfer technique includescoating a carrier film, such as polyester, with an embossable material,embossing and metalizing the composite. The film metalized embossedcomposite is laminated to a substrate product and the carrier film isnot removed, that is the image is viewed through the carrier film layerremaining on the product. It is desirable to have an image transfer filmtechnology in which the carrier layer can be removed, recovered and, toeven better advantage, recycled.

It is desirable to have a simpler, more easily utilized, less wastefuland lower cost method to transfer embossable metalized coating layers tosuitable substrates that does not employ a release layer.

U.S. Pat. No. 4,473,422 teaches a method for producing a metalized paperor board product having a bright surface and improved scratchresistance, comprising a transfer metalization technique utilizing a tiecoat applied to the metal layer and a pressure-sensitive, adhesive coatapplied to the tie coat, the adhesive coat binding the metalizedcomposite to the paper or board base. The adhesive coat is applied tothe paper or board base in the dry state and in combination with theadjacent tie coat, forms a hard, stable bond with the base thatfavorably withstands subsequent deformation of the paper or boardproduct. A top coat utilizing a particular solvent mixture, offersconsistent wettability of adhesive release coats, and provides a smooth,continuous outer surface for the final product. U.S. Pat. No. '422differs from the present invention in several ways. The presentinvention applies a coating to a base polyester film, which is thenembossed and metalized. The present base film is releasable after theembossing process has taken place.

U.S. Pat. No. 7,157,135 describes embossable films and methods formaking embossable films for creating holograms and diffraction gratings.The embossable films include a base substrate film and a co-extrudedembossable layer. The embossable layer is coated with a transparent highrefractive index (HRI) coating. The patented invention does not offertransfer release.

Transfer techniques to apply metallic coatings to substrates, such asfabric, leather or plastic surfaces, have been in use for a long time.Thus, the technique of gold leaf transfer was utilized in the 19thcentury by bookbinders, who employed gold foil transfer sheets to attachgold letters to leather bindings. The transfer sheets comprised a waxedcarrier web over which a sheet of gold foil was placed, the gold foilcoated on its free side with a heat-activated adhesive layer. Inpractice, the transfer sheet was hot pressed with a heated die to adherethe metal foil to the leather, and the carrier was thereafter strippedaway. The waxy parting layer that was coated initially over the carrier,served to maintain the gold leaf in position on the carrier prior to itstransfer, and to permit release of the carrier after the gold had beenaffixed to the leather.

In recent times, the advent of vapor deposition of metals, such asaluminum and the like, has spurred further interest in the use of thismetalization technique for the preparation of a variety of metalizedsubstrates. Thus, techniques of both direct and transfer coating havebeen attempted on a variety of base materials. There is a need for amethod to provide a metalized embossed composite material into asubstrate without requiring a release layer between the compositematerial and a barrier layer.

SUMMARY OF THE INVENTION

Disclosed is a releasable transfer film, suitable for providing ametalized embossed composite onto a substrate such as paper without arelease layer between the composite and a polymeric carrier layer. Thetransfer film includes a polymeric base layer, an embossing materiallayer and a metal layer. The transfer film is bonded to the substratewith an adhesive layer allowing the polymeric barrier layer to peel awayfrom and to expose the metal-backed, embossing material layer. Thesubstrate that is covered with the metalized embossed composite can beused to impart holographic style images to packaging and printed mediaproducts such as magazines. This invention provides an improvement inthe field of processing metalized embossed diffraction coatings onsubstrates in view that present day technologies do not allow for easytransfer and/or release of a base film after the embossable process hastaken place.

This invention thus provides a releasable metalized embossedtransferfilm comprising (a) a polymeric base layer, (b) an embossingmaterial layer in direct contact with the polymeric base layer, and (c)a metal layer in direct contact with the embossing material layeropposite the polymeric base layer, in which the polymeric base layer andembossing material layer have an interfacial joint formed by coating aliquid comprising an embossing material composition onto a surface ofthe polymeric base layer which surface has a surface energy less thanabout 60 dynes/cm, and in which the embossing material layer comprises apolymer having high toughness.

There is also provided a method of forming a releasable metalizedembossed transfer film comprising the steps of (A) providing a polymericbase layer defining a side having a surface energy in the range of about50-60 dynes/cm, (B) applying in direct contact with the side of thepolymeric base layer an embossing material layer comprising a polymericcomposition exhibiting an elongation at break of about 400-550%determined by ASTM method D882010, (C) embossing a surface on a side ofthe embossing material layer opposite the polymeric barrier layer inwhich the surface defines a diffraction grating pattern, and (D)depositing a metal layer of thickness in the range of about 20-50 nm onthe surface of the embossing material layer.

There is further provided a method of forming a light-diffractingmultilayer composite comprising the steps of (A) providing a polymericbase layer defining aside having a surface energy in the range of about50-60 dynes/cm, (B) applying in direct contact with the side of thepolymeric base layer an embossing material layer comprising a polymericcomposition exhibiting an elongation at break of about 400-550%determined by ASTM method D882010, (C) embossing a surface on a side ofthe embossing material layer opposite the polymeric barrier layer inwhich the surface defines a diffraction grating pattern, and (D)depositing a metal layer of thickness in the range of about 20-50 nm onthe surface of the embossing material layer, thereby forming areleasable metalized embossed transfer film, (E) providing a substrateand an adhesive layer on the substrate, (F) contacting the metal layerof the releasable metalized embossed transfer film with the adhesivelayer of the substrate, (G) activating the adhesive layer, therebybonding the releasable metalized embossed transfer film to thesubstrate, and (H) removing the polymeric base layer from the embossingmaterial layer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a cross section view of a composite of a polymeric carrierlayer and release layer as employed in conventional metalized embossedtransfer film technology.

FIG. 1B is a cross section view of the composite of FIG. 1A with anadditional embossing material layer.

FIG. 1C is a cross section view of the composite of FIG. 1B showing thesurface created by embossing of the embossing material layer.

FIG. 1D is a cross section view of a conventional metalized embossedtransfer film formed by adding a metal layer to the composite of FIG.1C.

FIG. 1E is a cross section view of the conventional metalized embossedtransfer film of FIG. 1D juxtaposed in relation to an adhesive coatedsubstrate.

FIG. 1F is a cross section view of the conventional metalized embossedtransfer film of FIG. 1E at stages of application to and removing fromthe adhesive coated substrate.

FIG. 1G is a cross section view of a product composite of a substrateand a metalized embossed film resulting from peeling the polymericcarrier and release layers away from the adhesive coated substrate ofFIG. 1F.

FIG. 2A is a cross section view of a novel polymeric base layer and anembossing material layer precursor composite for a releasable metalizedembossed transfer film according to the present invention.

FIG. 2B is a cross section view of a novel releasable metalized embossedtransfer film according to the present invention juxtaposed with anadhesive coated substrate.

FIG. 2C is across section view of the novel metalized embossed transferfilm of FIG. 2B at stages of application to and removing from theadhesive coated substrate.

FIG. 2D is a cross section view of a product composite of a substrateand a metalized embossed film resulting from peeling the polymeric baselayer from the novel metalized embossed transfer film and the adhesivecoated substrate of FIG. 2C.

DETAILED DESCRIPTION OF THE INVENTION

Aspects of this invention relate to a directly embossable, coated filmincluding, biaxially oriented polymer film, and a coating applied to thepolymer film. The base film can be any type of PET or PET type of film,any type of biodegradable film, as well as a variety of polyolefin filmssuch as polypropylene, polyethylene, etc. The coated surface issusceptible to embossing under heat and pressure as well as being ableto undergo transfer when used in conjunction with specified adhesivesand a method of producing a coated, directly embossable surface.

Accordingly, this invention provides a releasable transfer filmcomprising (a) a polymeric base layer, (b) an embossing material layerbeing in direct contact the polymeric base, and (c) a metal layer indirect contact with the embossing material layer, in which the polymericbase layer and embossing material layer have an interfacial joint formedby contacting the embossing material layer with the polymeric base layerhaving a surface energy of less than about 60 dynes/cm, and in which theembossing material layer comprises a polymer having high toughness. By“high toughness” is meant that tensile elongation at break is about400%-550% as calculated by ASTM method D882-10.

This invention also provides a method of forming a releasable transferfilm comprising the steps of (A) providing a polymeric base layerdefining side having a surface energy of less than about 60 dynes/cm,(B) applying to the polymeric base layer an embossing material layercomprising a polymer having high toughness such that the side of thebase layer is in direct contact with embossing material layer, (C)embossing the embossing material layer to form an embossed surfacedefining a diffraction grating pattern, and (D) depositing a metal layerof thickness in the range of about 20-50 nm on the embossed surface.

This invention further provides a method of forming a light-diffractingmultilayer composite comprising the steps of (A) providing a polymericbase layer defining a side having a surface energy of less than about 60dynes/cm, (B) applying to the polymeric base layer an embossing materiallayer comprising a polymer having high toughness, such that the side isin direct contact with the embossing material layer, (C) embossing theembossing material layer to form an embossed surface defining adiffraction grating pattern, (D) depositing a metal layer of thicknessin the range of about 20-50 nm on the embossed surface, thereby forminga releasable transfer film, (E) providing a substrate and an adhesivelayer on the substrate, (F) joining the releasable transfer film withthe substrate such that the metal layer is in contact with the adhesivelayer, (G) activating the adhesive layer, thereby bonding the metallayer to the substrate, and (H) removing the polymeric base layer fromthe embossing material layer.

The present invention can be explained in relation to a traditionalstructure and conventional multi-step process that may be understoodwith reference to FIGS. 1A-1G, FIG. 1A depicts a conventional polymericcarrier film 11 coated with a release layer R in an initial stage offorming a metalized embossing film. An embossing material layer 13 isplaced on the side of the release layer opposite the polymeric carrierfilm (FIG. 1B) and this preform composite is processed in an embossingoperation to produce a textured surface 14 (FIG. 1C) on the embossingmaterial layer 13. Following creation of the embossed surface, a metallayer 15 (FIG. 1D) is deposited on surface 14 of the embossing materiallayer 13. The metal layer is deposited by techniques that preferablymake the metal layer very thin. A multilayer composite with a thin metallayer is occasionally referred to as a “metalized film”. Because themetal layer is so thin, its surface contour 16 typically follows thecontour of the embossed surface 14 of layer 13.

The thus produced metalized embossed transfer film can be packaged forstorage and later use, or it can be used directly to deploy on asubstrate product. The latter utility is illustrated with reference toFIGS. 1E-1G Usually the metalized embossed film is to be applied to asubstrate in the form of a polymeric film 19. To bond the metalizedcoating layer to this film, the substrate 19 is coated with an adhesivelayer 17 (FIG. 1E). Next the metalized embossing film is placed adjacentto the adhesive coated substrate with the metal layer 15 in contact withthe adhesive layer 17 as shown at the left portion A of FIG. 1F. Theadhesive is activated to affix the metalized transfer film to thesubstrate.

Adhesive activation is preferably accomplished by exposure to heat andpressure. The adhesive layer 17 typically becomes soft and sufficientlyfluid to conform to the exposed textured metal surface 16 of themetalized film. The finished product is obtained by removing thepolymeric carrier film 11. The carrier film separates from the embossingmaterial layer 13 by peeling as seen in the right portion B of FIG. 1F.In conventional technology, the release layer R enables separationduring which the release layer and polymeric carrier film are removedtogether. This leaves a finished product, multilayer composite 10 of asubstrate 19 covered with a metalized embossed composite coating 13, 15,17 shown in FIG. 1G.

In general, the combination of materials of traditional transfer filmtechnology are selected to obtain suitable release characteristics. Thatis, the release layer composition is highly compatible with thepolymeric film layer. It is sufficiently compatible with the embossingmaterial layer that layer R will temporarily adhere to layer 13 duringthe production process including the optional packaging and storingsteps. However, the release layer is chosen to permit ready separationof the polymeric film and thus transfer of the metalized embossingmaterial layer to the substrate as described.

In contrast to the above-described conventional technology, the presentinvention provides a novel releasable metalized embossed transfer filmwithout a layer of release material positioned between a polymeric baselayer and the metalized embossing material. By proper selection ofmaterials and operating conditions according to this invention themetalized surface of the transfer film can be affixed to an adhesivecoated substrate after which the polymeric base layer, being in directcontact with the embossing material layer, can be peeled away therefrom.

An exemplary light-diffracting covered substrate product made by use ofthe novel releasable metalized embossed transfer film of this inventioncan be understood with reference to FIGS. 2A-2D. The product 20 (FIG.2D) has a structure comparable to that of multilayer composite 10 (FIG.1G). The novel releasable transfer film used to make multilayercomposite 20 is seen in FIG. 2A is built upon a polymeric base layer 21onto a side of which is placed an embossing material layer 23. Insubsequent fabrication steps, the exposed side of the embossing materiallayer is embossed to create a textured surface 14 (FIG. 2B). A thinlayer of metal 15 is deposited on textured surface 14 to form a metallayer also with textured surface 16. The embossed and metalized transferfilm 22 is then juxtaposed in relation to a substrate component, such aslayer 19 on which is positioned an adhesive layer 17, this adhesivecoated substrate being designated as composite 24.

In still further steps, the metalized embossed transfer film 22 islaminated to the substrate composite 24 of the substrate layer 19 coatedwith the adhesive layer 17. The two composites 22 and 24 are broughtinto contact as seen in left portion A′ of FIG. 2C. While in contactadhesive 17 is activated such that transfer film 22 joins to substratecomposite 24. Optionally, heat and/or pressure can be applied to createthe sealing bond of the adhesive layer 17. At this stage the polymericbase layer 21 is peeled away from the technical back surface 25 of theembossing material layer 23. This is seen in the right portion B′ ofFIG. 2C. Because of the selection of polymeric base layer and embossingmaterial layer composition, the base layer can adhere satisfactorily tothe technical back surface of the embossing layer for purposes of makingthe metalized embossing material layer and assembling the productcomposite 20 (FIG. 2D). Yet the adherence is weak enough that thepolymeric base layer can be pulled off of the product composite leavingsubstantially all of the metalized embossing layers intact and bonded tothe substrate 19 by adhesive layer 17. No release layer is used.

In a preferred embodiment the embossing step produces a pattern ofdiffraction grating lines. Thus light impinging on the outer surface 25of the embossing material layer will be diffracted when reflected fromthe metal layer 15, thereby producing a holographic style effect.

Suitable metal layer materials used herein include Al, Au, Ag, Cu, Pt,Ni, Ti, Ta and mixtures thereof. The metal layer is generally at athickness of about 20-50 nm. Many thin film metal deposition techniquescan be used, such as chemical vapor deposition, sputtering and the like.The metal layer is preferably applied by vacuum deposition.

The adhesive is selected with the objective of providing a strong bondbetween the metal layer and the substrate. In fulfilling this objective,the adhesive layer thus affixes the metal side of the metalizedembossing material film to the substrate. The adhesive layer is selectedfrom the group consisting of polyester, internally or externallyplasticized copolyester, internally or externally plasticized acrylics,epoxy-based resins, PVA (polyvinylacetate) based resins,polyurethane-based laminating adhesive and the like. The compositionsutilized in layers 15, 17, and 19 are substantially the same those inconventional transfer films that use a release layer. However, thestrength of this bond should be greater than that between the polymericbase layer and the embossing material layer to assure that peeling ofthe base layer from the product composite 20 does not cause themetal-to-substrate bond fail.

Typical examples of substrate are paper, paper like sheets or film,polymeric film and fabrics. The adhesive can be any strong composition.A pressure sensitive adhesive is preferentially contemplated.

Preferred compositions for the polymeric base layer are polyester,polyhydroxy acid and polyolefin. To obtain satisfactory releasableadhesion of the base layer to the embossing material layer, it isdesirable to induce a surface energy of the coat-carrying side at about50-60 dynes/cm, preferably 50-58 dynes/cm and more preferably thesurface energy should be about 54 dynes/cm. The surface of the side ofthe base layer facing the embossing material layer can be treated beforeapplying the coating layer as appropriate to obtain surface energy inthe desired range. Surface treatment methods such as corona treatmentmay be used.

It is also important that the composition of the embossing materiallayer be such that this layer remains intact when the carrier is peeledaway. Thus the embossing material should be suitably tough. That is, theembossing material should have suitable intrinsic structural integrity.Toughness for this purpose is primarily measured by the tensile strengthproperties of the embossing material, and particularly elongation atbreak. Preference is given to polyurethane as the composition of theembossing material layer. A polyurethane with tensile elongation atbreak of about 400%-550% is preferred as determined by ASTM analyticalmethod D882-10.

EXAMPLES

A tape transfer test was used in the examples, as follows. After asubstrate was coated with a test composition, the coating was dried toform a layer on the substrate and 3M® 810 tape was pressed onto thesurface with a 2 lb (908 g) rubber roll. The tape was then brisklypulled from the sample at an angle of 180 degrees. The amount of coatedlayer removed from the sample by the tape was given an estimatednumerical value of the percentage of area of the transferred based onvisual examination. Accordingly, 0% indicates that none of the coatedlayer was transferred and 100% indicates that all of the coated layerwas removed from the substrate. Three trials were performed for eachexperiment and the average values were reported. The tape transfer testwas meant to simulate the ability of the tested embossing materiallayers to adhere from the tested substrate film to the 3M taperepresenting an adhesive coated product substrate (i.e. film 24 FIG.2B). Due to the subjective nature of the visual examinationdetermination of transferred material, a value of 90% or was deemedacceptable.

Embossing evaluation of the example films was done as follows: A hotroll laminator (ChemInstruments, Fairfield, (H) with an 18 inch (46 cm)wide, hot roll and matching 18 inch wide rubber backing roll was used toemboss test film material. A 4 inch by 4 inch (10 cm by 10 cm) nickelembossing shim was placed on top of the sample to be tested. The nickelembossing shim used was selected from among a series of difractiongrating lines of depths in the range of 0.05 to 0.2 μm, the lines beingarranged in a variety of patterns such as “starburst” and “circle withina circle” designs. Both rolls were heated to 220° F. (104° C.). The filmsample and shim were passed together into the nip between hot roll andbacking roll at a speed setting of approximately 10 feet/minute (3m/min.) with a nip pressure of 400 psi (2.8 Mpa). The sample was removedand placed on a bench top to cool to room temperature. The film was thenslowly peeled off the shim at a 45 degree angle so as to preserve theimage impressed into the embossed material. To enhance visibility of theembossed image, the sample was placed on a black background and examinedunder flourescent lighting by visual inspection for embossing quality.Embossing quality was rated as follows: “Excellent” for bright colorsviewed from many angles with no unembossed areas, “Good” for slightlyattenuated color brightness viewed from multiple angles, “Fair” formoderately attenuated color brightness, and “Poor” for dull colors andunembossed areas.

The surface energy of the samples were measured by applying a series ofAccu Dyne Test solutions (Diversified Enterprises, Claremont, N.H.) tothe sample surface with cotton swabs. The solutions are liquidscalibrated to surface energies in the range of 30-70 dynes/cm. Thesurface energy of the sample was indicated by the designation of thehighest dyne-valued test solution that wetted the surface withoutbeading.

Coat weight was measured by the following gravimetric method. A coatedsubstrate to be analyzed was dried and cut to a sample size of 4 inch by4 inch (10 cm by 10 cm). The sample was weighed on an analytical balancewith at least 2 decimal place accuracy. The coating was then removed bydissolving the coating composition in a solvent such as acetone. Thesample was dried and weighed again. The difference between the coatedand uncoated sample was reported as the dry coat weight in grams persquare meter or “gsm”.

In the samples percentages are by weight unless indicated otherwise.

Comparative Example 1

An acrylic embossing material composition in aqueous medium was coatedonto a polyester film. The embossing material composition coating liquidincluded 49% Setaqua™ 6472 acrylic copolymer emulsion (Nuplex Resins,LLC, Louisville, Ky.), 2% Dowanol PPH (Dow Chemical Co., Midland,Mich.), 0.5% Chemslip 25 wax, (ChemCor, Chester, N.Y.), and 0.2%Surfynol® 440 surfactant (Air Products and Chemical, Inc., Allentown,Pa.). The acrylic copolymer in Setaqua 6472 is a thermoplastic with aglass transition temperature (“Tg”) of 40° C. Dowanol PPH is acoalescent glycol ether serving as a temporary plasticizer. Chemslip 25is a synthetic wax emulsion used here as an embossing shim release aid.Surfynol 440 surfactant is a 100% active liquid, ethoxylated wettingagent and defoamer serving here to reduce the surface tension of theliquid embossing material composition which aids in the wetting of thesolution to the substrate. The aqueous embossing material compositioncoating liquid was applied to the polyester film and the water wasremoved by drying. The composition was applied to the film at a rateeffective to achieve a dried embossing material layer thickness of 0.1to 0.4 μm. The transfer film was analyzed for embossing quality and fortransfer from the base layer by the tape test. This acrylic polymerbased composition was rated excellent for embossing but provided 0% tapetransfer. Although it is a very good embossing material, it lacked thetoughness to be completely released from the polyester base layer filmto the tape.

Comparative Example 2

The procedure of Comp. Ex. 1 was repeated except that Setaqua 6472 wasreduced to 44%, and 5% TEGO® ADDBOND DS 1300 (Evonik Tego Chemie GmbH,Germany), modified polyester containing dimethyl amino ethanol and 0.7%Chemcor 392N35 nonionic high density polyethylene were substituted forthe Chemslip 25 and Surfynol 440 components in the embossing materialcomposition. Embossing quality rating was excellent and tape transferwas 0%.

Comparative Example 3

The procedure of Comp. Ex. 1 was repeated except that 0.2% Tego 505, analkoxylated alcohol (Evonik Tego Chemie) was added to the embossingmaterial composition formulation. Tego 505 was intended to serve asrelease agent and surfactant to increase release of the acrylicembossing layer. Tape transfer increased to 80%, however, embossingquality was poor.

Comparative Example 4

A coating liquid of 80% Neocryl BT 67 from DSM Neoresins and 20% of 10%solids Polyox N80 was prepared. Neocryl BT67 is a 0° C. Tg anionicacrylic emulsion and Polyox N80 is a water soluble polyethylene oxidethermoplastic resin. The liquid was coated onto a polyester film, dried.Embossing quality was rated as good but tape transfer was 20%.

Comparative Example 5

The procedure of Comp. Ex. 1 was repeated except that Polyox N80polyethylene oxide was added to the embossing material composition andproportions of the components were adjusted to 40.6% Setaqua 6472, 1.8%Dowanol PPH, 0.43% Chemslip 25, 0.17% Surfyno 440, and 17% Polyox N80.This embossing material composition did have good embossing quality buttape transfer was only 80%.

The above experiments show that an acrylic based embossing layer asapplied was too weak to transfer substantially as an integral unit fromthe base layer to the adhesive tape substrate.

Example 1

Solucote 1051i-2-25 (DSM NeoSol Inc., East Providence, R.I.), Solucote1051i-2-25 was coated using a No. 4 mayer rod coating system onto anon-surface treated polyester film having surface energy measured at 52dynes/cm. Solucote 1051i-2-25 is a 35% nonvolatile content, aqueousemulsion of aliphatic urethane. The coated film was dried in an oven at190° C. for 15 seconds producing a 2.6 g/m² polyurethane embossingmaterial layer with elongation of 470%. The coated film was embossed at210° F. (99° C.) and produced an excellent embossing quality rating. Theembossed layer transferred readily to the adhesive tape in the tape testto yield a 100% tape transfer value.

Comparative Example 6

The procedure described in Ex. 1 was repeated except that prior tocoating with the embossing material liquid, the polyester substratesurface was corona treated using a handheld BC20AC laboratory coronatreatment device. The treated surface had surface energy of 60 dynes/cm.The dried embossing layer had a 2.6 g/m² weight and produced andexcellent embossing quality rating. However, the tape transfer test gavea measurement of 20% indicating that adhesion to the base layer hadincreased significantly due to corona treatment, hence the embossingmaterial layer would not transfer well to the adhesive tape.

Comparative Example 7

The procedure described in Ex. 1 was repeated except that the urethanesolids in the coating emulsion was reduced to 15% by adding water. Thesurface energy was 52 dynes/cm, as in Ex. 1, and embossing qualityrating was excellent, however the lower embossing material concentrationyielded lower transfer to the tape. Because of the diluted coatingliquid, the dry weight of the embossing layer was 1.14 g/m². Thethickness of embossing layer was insufficient to maintain structuralintegrity to peel as a unit from the substrate despite the propersurface energy.

Comparative Example 8

The procedure described in Comp. Ex. 3 was repeated except that thepolyester base layer film was corona treated to a surface energy of 60dynes/cm prior to coating with the polyurethane embossing materiallayer. The embossing layer weight on the base layer film was again 1.14g/m². Because of the increase of surface energy and adhesion to the baselayer coupled with the light coating of embossing material, only 15%embossing material layer transferred to the tape demonstrating that theembossing material layer was too thin for strength to cohesivelytransfer from the substrate. Embossing quality rating of the embossingmaterial layer was excellent.

In the following examples, a series of releasable embossing metalizedtransfer films were prepared by coating a polyurethane embossingmaterial onto a polyester film. The polyurethane compositions in theseries had different degrees of elasticity. The liquid coatingcompositions were applied to the polyester film with a Mayer coatingtechnique using a No. 3 Mayer rod. The amount of water medium for all ofthe liquid coating compositions and feed conditions were adjusted toachieve an embossing material layer weight of approximately 2.0 g/m²after drying in an oven at 230° C. for 15 seconds. The coated films werethen embossed with a hot roll laminator as described above. The embossedsurface of the samples were metalized (i.e., overcoated) with aluminumin a bell jar vacuum metalization chamber. After metallization, thealuminum coating had optical density of about 2-3. Embossing quality,elongation at break and tape transfer were measured for each releasablemetallized embossing film.

Comparative Example 9

Utilized for the embossing material Neorez® R-986 (DSM Neoresins,Waalwijk, NL) an emulsion of aliphatic urethane providing low elasticitypolyurethane embossing material layer with good tape transfer (90%) butpoor embossing quality. Elongation at break was 160%.

Comparative Example 10

Utilized DSM Neoresins Neorez R-9621 aliphatic polyester urethanedispersion. The embossing material layer provided very high (630%)elongation with good embossing quality. Tape transfer was 0% indicatingtoo much adhesion of embossing layer to the base layer film.

Comparative Example 11

The embossing material was Bondthane™ UD 250 (Bond PolymersInternational LLC, New Hampshire,). Elongation at break was low (200%),embossing quality was very poor, and tape transfer was 50%.

Example 2

Utilized Bondthane UD 211 for the embossing material and the analyticalresults were at the limit of acceptability for a releasable metalizedembossing transfer film (elongation at break 400%, embossing qualityfair, and tape transfer 90%.

Example 3

Utilized DSM Neoresins Solucote 1051 I-2-25, an aliphatic polyurethanedispersion and included a 5% concentration of Surfynol 420 surfactant.The embossing material composition developed superior analytical resultsof 470% elongation at break, excellent embossing quality and 100% tapetransfer.

Example 4

Used DSM Neoresins Solucote 1372, an aliphatic polyurethane dispersionwith no surfactants. Elongation at break was again 470% and embossingquality was excellent. Release property determined by tape transfer testwas slightly lower than Ex. 3, perhaps due to lack of surfactant.Nevertheless, the 95% tape transfer value was deemed acceptableperformance for the releasable metalized embossed transfer film.

Although specific forms of the invention have been selected in thepreceding disclosure for illustration in specific terms for the purposeof describing these forms of the invention fully and amply for one ofaverage skill in the pertinent art, it should be understood that varioussubstitutions and modifications which bring about substantiallyequivalent or superior results and/or performance are deemed to bewithin the scope and spirit of the following claims. All U.S. patentsand patent applications identified in this disclosure are herebyincorporated by reference herein.

What is claimed is:
 1. A releasable metalized embossed transfer filmcomprising (a) a polymeric base layer, (b) an embossing material layerin direct contact with the polymeric base layer and having an embossedsurface on a side opposite the polymeric base layer, the embossedsurface defining a diffraction grating pattern, and (c) a metal layer indirect contact with the embossing material layer opposite the polymericbase layer, in which the metal layer comprises as a major fraction ametal selected from the group consisting of Al, Au, Ag, Cu, Pt, Ni, Ti,Ta and a mixture thereof, and in which the metal layer has a thicknessof about 20-50 nm, and in which the polymeric base layer and embossingmaterial layer have an interfacial joint formed by coating a liquidcomprising an embossing material composition onto a surface of thepolymeric base layer which surface has a surface energy less than about60 dynes/cm, and in which the embossing material layer comprises as amajor fraction polyurethane having elongation at break in the range ofabout 450-500% as determined by ASTM method D882-10.
 2. The releasablemetalized embossed transfer film of claim 1 in which the surface energyis at least 50 dynes/cm.
 3. The releasable metalized embossed transferfilm of claim 1 in which the polymeric base layer comprises as a majorfraction a polymer selected from the group consisting of polyester,polyhydroxyacid, polyolefin and a blend thereof.
 4. The releasabletransfer film of claim 1 in which substantially all of the embossingmaterial layer and metal layer is peelable intact from the polymericbase layer.